DE2943947A1 - TWO-STAGE EJECTOR ARRANGEMENT FOR A MOLD MOLDING TOOL - Google Patents

Description

P 127/2 DE

HANS MÜLLER, S-502 44 BORAS (SWEDEN)

as well as NILS GUNNAR NILSSON ^ S-520 15 HÖKERUM (SWEDEN)

Two-stage ejector arrangement for an injection molding tool

The invention relates to a two-stage ejector arrangement for an injection molding tool.

October 29, 1979
V / v

030022/0588

P 127/2 DE ~ / ~

With some injection molds, two-stage ejectors must be used. This is for example at the production of products that have undercuts. In such a case, the first Part of the ejector movement is used to remove the parts with the undercuts of the article from the side Pulling out the tool, and only after the end of this string movement will the article actually be removed from the tool Injection tool ejected.

The known ejector arrangements are too complicated and work too slowly.

The present invention is based on the object of creating an ejector arrangement with which a simpler can be operated and operated more effectively, and by which the disadvantages of the known arrangements can be overcome can be.

According to the invention, the object is achieved by the characteristics of the main claim listed features solved.

The invention is based on an exemplary embodiment by means of Drawings explained. Show it

030022/0588

P 127/2 DE - V-

Fig. 1 is a longitudinal section through the inventive Ejector assembly in its pre-eject operating state with the ejector pin plates in their retracted position,

Fig. 2 is a longitudinal section through the same ejector assembly, with one of the ejector pin plates a Has reached the end position,

3 shows a similar longitudinal section of the ejector arrangement in a position where the second Aus

throw pin plate has reached an end position,

Fig. 4 is a partial section on an enlarged scale of the

with a circle denoted detail in Fig. 1, and finally

Fig. 5 is a front view of a ring connected to the injection molding tool.

The drawings (FIGS. 1, 2, 3) show the rear section of an injection molding tool 1. The section shown comprises a rear holding plate 2 of the injection molding equipment as well as a first ejector plate 3 and a second ejector plate 4. The purpose of these two plates is to the ejector pins and similar means to hold and hold them

Q3QQ22 / 0588

P 12 7/2 DE

to move, and therefore each of them consists of two with each other attached plates between which the heads of the ejector pins are held, as shown in the Drawing can be seen.

The holding plate 2 is preferably equipped with a central, through opening 5, and the one ejector plate 3 is similarly equipped with a preferably centrally arranged threaded bore 6, and the one plate of the ejector plate 4 has a bore 8 which is provided with a chamfer 7, whereby a threaded pin 9 is held in the manner shown in FIG. The individual parts of the ejector plates are by means of Screws or rivets fastened together.

The new ejector assembly 10 consists of one unit. It includes a ring 11 attached to the rear plate of the injection molding tool is attached by means of screws 12 and has an internal thread 13, as shown in FIG. 5 you can see. The ring has a slot 14, and by means of a screw 15 its legs are so against each other pressed that the diameter of the ring 11 is reduced.

The ejector assembly is also provided with an adjustment sleeve

030022/0588

P 127/2 DE "Υ '

29A39A7

which has an external thread 17 which engages in a corresponding internal thread 13 of the ring 11. the Adjustment sleeve 16 also has a knurled part 18 and is provided with an annular groove 19 on the inside.

An ejector sleeve 20 is movably supported in the adjusting sleeve 16, and one end is the ejector sleeve provided with an external thread 21 which engages in an internal thread of the threaded hole 6 in the ejector plate 3. The extension of the thread in the ejector plate 3 is limited by a flange 22. The ejector sleeve 20 has a number of vertically arranged bores 23, the purpose of which will be described below. The ejector sleeve is provided at its end and opposite the external thread with a thread 24 limited by a flange and engages in a corresponding thread of a stop ring 25, which controls the axial movement of the ejector sleeve 20 limited to the left, as can be seen in the drawing, where a stop at the right end of the adjusting sleeve 16 takes place.

Coupling segments 27 are inserted into the vertically arranged bores 23 of the ejector sleeve 20. These segments are shown on an enlarged scale in FIG. From it it is clear that the edges of the segments with

030022/0588

P 127/2 DE

Chamfers 28 are provided. The sections which are directed towards the central part of the ejector sleeve (FIG. 4) have beveled surfaces 29, the angle tt of which exceeds 45 ° for a purpose to be described further below.

Finally, the ejector according to the invention also includes an ejector pin 30 with a threaded hole 31 at its left end (Fig. 1), this threaded hole is for this purpose because to enable the threaded pin 9 to be screwed in. This is provided with an annular groove 32 (FIGS. 1, 4) which is arranged between the ends of the ejector pin 30. The ejector pin is next to a key profile 33 its right end and its right end carries an adapter 34 for connecting an ejector mechanism. However, the ejector can also be operated without the separate use of a special ejector mechanism be, and this is done by the fact that the ejector pin when opening the injection molding tool to a stationary Part strikes in the injection molding machine.

The arrangement described is easy on a compression molding tool by tightening the ring 11 at the rear Mounting plate of the same attached, and by tightening the ejector pin by means of a in the key profile 33 engaging tool. The intensity of the

030022/0588

P 127/2 DE - 7 / -

Shock can be adjusted that the adjusting sleeve 16 is rotated with respect to the ring 11 when the screw 15 is loosened and such a rotation permitted. The position found is then fixed by tightening the screw 15.

The ejector assembly works in the following way:

When the ejector pin 30 - based on FIG. 1, 2, 3 - moved to the left during the injection process (in reality it is the tool that moves, while the ejector pin no longer performs any movement after it has hit the part that is fixed to the housing; to the However, for the sake of clarity of description, the movement will be described as if the ejector pin were moving 30 to the left), the ejector plate 4 also moves. Since the ejector sleeve 20 with the ejector pin is connected via the coupling segments 2 7, which do not loosen their connection with the ejector pin 30, the ejector sleeve 20 and the ejector plate 3 attached to it will also have the same movement with the ejector pin 30 run. The inclined surface 29, which delimits the annular groove 32 and rests against it, leads to the fact that a force is exerted on the inner surface of the adjustment sleeve 16. So that this force does not become unbearably great, is the angle OC made relatively large.

G3GG22 / G588

P 127/2 DE - y ~

. A Λ ·

During this part of the ejector movement, the ejector plates 3 and 4 moved in the axial direction. A change occurs when the ejector pin runs out Fig. 2 has reached the position shown, wherein the annular groove 19 of the adjusting sleeve 16 with the corresponding Annular groove 32 in the ejector pin 30 covers. In this position, the coupling segments 27 can come out of the ejector sleeve 20 outwardly so that the engagement with the ejector pin 30 is released. The coupling segments are thus pressed radially outward due to the beveled surfaces 29 so that they are in the adjustment sleeve 16 slide in, whereby the engagement with the ejector pin and the ejector sleeve is released. As soon as this State is reached - if the ejector pin continues its forward movement - the ejector sleeve fixed in the position shown in FIG. 2, which is determined by the stop ring 25 and the position of the annular groove 19 is. As can be seen from Fig. 2, an exact axial securing of the ejector sleeve is achieved in that the annular groove 19 is made wider than the coupling segments.

When the ejector pin 30 moves further, the ejector plate 4 is also moved, but the ejector plate 3 remains in the position shown in FIG.

030022/0588

P 127/2 DE -

/ Il

<■} h ^ 9 A 7

The end position of the arrangement is from rig. 3 can be seen.

When the auiiwci icrvorqnng has been completed, return the individual parts in their Ausqanqslage according to Fiq. 1 back again.

As noted above, the rtofi can be used for ejection in that the degree of attachment of the adjusting sleeve in the ring 11 is varied. Since the end face of the setting sleeve If has a movement stroke executes, which corresponds to that of the annular groove 19 is the circular axial attachment of the Ejector sleeve received in relation to the adjustment sleeve remain, regardless of the position of the adjustment sleeve. Although the embodiment is with two ejector plates has been described, but it should be noted that a single ejector plate with only one central ejector can be provided, and other combinations can be used. To the ejector keep applicable even if one of the ejector plates carries an ejector st i ft, the ejector pin 30 is provided with a hole 35 according to the drawing, which has a level floor as a conclusion.

The Axiswerf sleeve 20 {Fi-g. D has a taper 26 between the stop ring 25 and the annular groove 32.

030022/0588

Claims (5)

P 127/2 DE Claims Two-stage ejector arrangement for an injection molding tool or the like, characterized in that a first ejector pin (30) is provided, which is used directly for the ejection process and together with an ejector plate (4) or the like acts, which can assume a first and a second ejection position, and that a second Ejector means in the form of an ejector sleeve (20) is provided, which is connected to a second ejector plate (3) or the like cooperates, which is only moved during the first ejection process, and that coupling segments (27) are provided, the movement of the ejector sleeve (20) during a predetermined, allow the first part of the ejector movement of the first ejector part and then the ejector pin Separate (30) from the ejector sleeve (20) and connect the ejector sleeve (20) to an adjustment sleeve 0-6), which is firmly connected to the tool. 2. Arrangement according to claim 1, characterized in that the first ejector means as October 29, 1979
V / v 030022/0588 ORIGINAL INSPECTED P 127/2 DE - γ. - Ejector pin (30) is designed, while the second ejector means comprises an ejector sleeve (20), which is movable relative to the ejector pin, and wherein the ejector sleeve relative to the adjustment sleeve (16), which is connected to the injection molding tool, is movable, and that the coupling means is an annular groove (32) in the ejector pin (30), a number of holes (23) in the ejector sleeve (20) arranged radially in it and comprise coupling segments (27) which are in the Bores run, the segments have radial lugs with which they protrude into the adjustment sleeve, so that they protrude into the annular groove of the ejector pin or into the annular groove (19) in the adjusting sleeve (16), which is connected to the injection molding tool. 3. Arrangement according to claim 1, characterized in that the adjusting sleeve (16) is preferably is adjusted in that it is screwed to part of the injection molding tool. 4. Arrangement according to claims 1 and 2, characterized in that the coupling segments (27) have beveled surfaces (29) with which they engage in inclined surfaces that form the annular groove (32) of the ejector pin (30). 030022/0588 P 127/2 DE - l / '- 5. Arrangement according to claims 1 and 2, characterized in that the ejector sleeve (20) has a stop ring (25) with which it strikes against a stop surface of the adjusting sleeve (16) in an end position thereof, and that the position of the stop so is chosen that the annular groove (19) of the
Adjustment sleeve (16) with the coupling segments (27)
aligned when the stop ring (25) is in his
End position is. 030022/0588